Pyrolysis of acetylene in sonolytic cavitation bubbles in aqueous

J . Phys. Chem. 1990, 94, 284-290

284

in winter, since preliminary results of a recent campaign26show that no BrO was detected during the night, whereas daytime mixing ratios ranging from 2 to 8 pptv were measured. Similarly to the Antarctic stratomhere. high abundance of OClO was also found. These observahons seem to confirm that the reaction between and ‘lo may play a significantrole under the polar ,

I

stratospheric conditions either in the formation and variation of OClO or in the sequestration of BrO into BrCI. The latter effect is revealed by the new laboratory data presented in this paper and in that of Fried1 and Sander.24 Acknowledgment. This work has been performed under contract with the French Ministrv of Environment. We also thank

(26) “Airborne Arctic Stratospheric Expedition February 1989.

Pyrolysis of Acetylene In Sonolytic Cavitation Bubbles in Aqueous Solution Edwin J. Hart, Christian-Herbert Fischer, and Arnim Henglein* Hahn-Meitner-Institut Berlin GmbH, 1000 Berlin 39, Federal Republic of Germany (Received: April 14, 1989)

Water was irradiated with 1 MHz ultrasound (about 2 W/cm2) under mixtures of argon and acetylene of various compositions. A few experiments were performed using deuterated acetylene. Acetylene is rapidly consumed, the maximum rate occurring at a solution concentration of C2H2of 2 X M. The products are H2, CO, CH4, a great number of hydrocarbons containing two to about eight C atoms, formic and acetic acids, formaldehyde and acetaldehyde, and insoluble soot. Some larger product molecules are benzene, isomers of benzene, phenylacetylene, styrene, and naphthalene. The products are similar to the ones observed in the pyrolysis and combustion of acetylene. The relative abundancies of the products change with acetylene concentration, which is in part attributed to the varying temperature of the adiabatically compressed cavitation bubbles. All products are initially formed proportional to the irradiation time, even at times in the 10-s range. Volatile products are, however, consumed in longer irradiations. It is concluded that all products are formed in single cavitation events and not by stepwise formation and subsequent sonolysis of intermediate compounds in different cavitation bubbles. A mechanism is proposed according to which water vapor decomposition is the main primary process at low C2H2concentration, the OH radical and H and 0 atoms formed attacking acetylene molecules. At higher C2H2concentrations, the direct pyrolysis of acetylene is the principal primary process, C4H, and C4H4being formed as the most important precursors of the higher C atom number products. Among the latter, even C atom numbers are more abundant than odd numbers. Small soot molecules form a colloid absorbing uniformly at all wavelengths in the UV/vis region, and larger molecules mainly scatter light. The results are discussed in terms of mechanisms developed in combustion chemistry.

Introduction The chemical effects of ultrasound in aqueous solutions containing argon are due to the high temperatures in gas bubbles which are formed and compressed as a consequence of the periodic pressure changes in the liquid.] Two kinds of reactions may be distinguished: (1) reactions occurring directly in the hot gas bubbles, and (2) reactions in the solution as free radicals generated in the gas bubbles reach the liquid phase.2 Solutes of high vapor pressure can readily move into the bubbles and undergo pyrolysis in the gas phase. Solutes of low vapor pressure are chemically changed by free-radical attack in solution, although even these compounds (such as ionsZband polymers3) can also be pyrolyzed in the hot interface between bubble and solution. During the past few years many gas-phase reactions, such as H2-D2 isotope ex~ h a n g e lsN,-14N2 ,~ isotope e x ~ h a n g e l*02-160H2 ,~ isotope ex( I ) (a) Elpiner, I. E. Ultrasound, Physical, Chemical and Biological EJ fects; Consultants Bureau: New York, 1964. (b) Weissler, A. In Encyclopedia of Chemical Technology, 3rd ed.; Kirk, R. E., Othmer, D. F., Eds.; Wiley-Interscience: New York, 1981; Vol. 15, p 773. (c) Flynn, H. G. In Physical Acoustics; Mason, W. P., Ed.; Academic Press: New York, 1964; Vol. IB, Chapter 9. (d) Neppiras, E. A. Phys. Rep. 1980, 61, 159. (e) Henglein, A. Ultrasonics 1987, 25, 6. (f) Suslick, K. S. Ultrasound, Its Chemical, Physical and Biological Effects; VCH Publishers: New York, 1988. (9) Mason, T.; Lorimer, J. P. Sonochemistry: Theory, Applications and Uses of Ultrasound in Chemistry; Ellis Horwood: Chichester, U. K., 1988. (2) (a) Sehgal, C. M.; Wang, S: Y. J . Am. Chem. SOC.1981, 103,6606. (b) Gutrerrez, M.; Henglein, A.; Fischer, Ch.-H. Int. J . Radiat. Biol. 1986, 50, 313. (3) Henglein. A.; Gutibrrez, M. J. Phys. Chem. 1988, 92, 3705. (4) Fischer, Ch.-H.; Hart, E. J.; Henglein, A. J . Phys. Chem. 1986, 90, 222.

0022-3654/90/2094-0284$02.50/0

change,6and nitrous oxide’ and ozone8 decomposition have been studied. These reactions generally occur with more than 10 times greater yields than the liquid-phase reactions. Studies on the sonolytic decomposition of pure hydrocarbons have been carried out by Suslick et aL9 Simple hydrocarbons, such as methane and ethane, in aqueous solution have been studied in our laboratory.I0 In these experiments, water was irradiated under an argon atmosphere to which a certain amount of hydrocarbon gas had been added. The yields of the various products of sonolysis were determined as functions of the hydrocarbon concentration. With increasing amount of hydrocarbon in the argon bubbles the yields first increase as there is more and more reactant concentration. However, because of the lower ratio, 7 , of the specific heats of the hydrocarbon (as compared to that of argon) the temperature reached in the adiabatic compression of the bubble becomes lower with increasing hydrocarbon content of the bubble. The two effects generally lead to a maximum in the yield vs hydrocarbon concentration curve. In addition, the spectrum of the products may change. For example, C2H2and C2H4are formed in the sonolysis of methane, and from the ratio of these products one may calculate the bubble temperature for (5) Hart, E. J.; Fischer, Ch.-H.; Henglein, A. J . Phys. Chem. 1986, 90, 5989. (6) Fischer, Ch.-H.; Hart, E. J.; Henglein, A. J . Phys. Chem. 1986, 90. 1954.

(7) Hart, E. J.; Henglein, A. J . Phys. Chem. 1986, 90,5992. (8) Hart, E. J.; Henglein, A. J . Phys. Chem. 1986, 90, 3061. (9) Suslick, K. S.; Gawienowski, J. J.; Schubert, P. F.; Wang, H. H. J. Phys. Chem. 1983,87, 2299. (10) (a) Henglein, A. Z. Naturforsch. 1985, 40b 100. (b) Hart, E. J.; Fischer, Ch.-H.; Henglein, A. J . Phys. Chem. 1987, 91, 4166.

0 1990 American Chemical Society

Pyrolysis of Acetylene

The Journal of Physical Chemistry, Vol. 94, No. 1 , 1990 285

various argonmethane ratios" making use of known kinetic data in combustion chemistry.12 In these studies on methane and ethane it was found that acetylene is an important product. Further, hydrocarbons of longer chain lengths were observed and it was reasoned that intermediate acetylene played a role in the buildup of these products. It was therefore decided to study the sonolysis of acetylene. As in the preceding work, aqueous solutions containing various mixtures of argon and acetylene were sonicated. It turned out that the decomposition rate of acetylene is very high. In some experiments, sonication times as short as a few seconds had to be applied to work under conditions where kinetic measurements are meaningful (i.e., at practically constant C2H2concentration).

Experimental Section The ultrasound was generated by a 1-MHz quartz generator. The generator and the irradiation vessels have been described previ~usly.'~The vessels contained 37.5 mL of solution and 22.5 mL gas phase. They were closed during irradiation. The liquid was agitated by ultrasound as a small fountain was produced on the surface. This agitation was necessary to secure rapid equilibration of the solution with the gas atmosphere during irradiation. In some experiments a stream of an argon-acetylene mixture passed through the solution during irradiation to carry away the volatile products. The identification of the volatile and nonvolatile compounds falls into five categories: 1. The simple volatile gases, consisting of H2, CHI, C2H6,C2H4, C2H2,CO, and C 0 2 were analyzed on a Delsi gas chromatograph. Molecular sieve and Porapak columns were used. These gases were removed from the equilibrated vapor above the irradiated solution by transfer from the irradiation vessel into a Van Slyke manometric chamber and from there into an evacuated gas sample tube. 2. The group of gases consisting of hydrocarbons C2's through the C4's were analyzed on a Hewlett Packard 5890A gas chromatograph (50-m AI2O3/KCI fused-silica column; 0.32-mm internal diameter). The compounds consisted of propane, allene, propene, propyne, isobutane, n-butane, butadiene, and 1-butyne. 3. The hydrocarbons consisting of the C5's through the Cs's were not found in the equilibrated gas phase. They were removed from the solution by a flowing mixture of C2H2-Ar during irradiation. These products were condensed in a small trap cooled to -80 "C by a C02-acetone mixture. The products in this trap were extracted with ether or methanol and then analyzed in a UV spectrophotometer and in a mass spectrometer combined with a gas chromatograph. 4. The nonvolatile higher molecular weight hydrocarbons were extracted from the irradiated solution (saturated with NaC1) with diethyl ether. This extract was injected into a heated gas chromatograph column connected to a mass spectrometer. This extract contained hydrocarbons within the mass range of 100-200. In one case (Figure 10) 250 pL of chloroform was used for extraction after 1 1 g of NaCl had been added to the irradiated solution. 5. The irradiated solutions contained compounds of rather large molecular weight which scattered light. Their relative concentration was followed by measuring the scattering absorbance at 300-800 nm in a spectrophotometer. About 50% of the particles scattering could be removed by a 0.45-pm filter. On standing or during prolonged irradiations the colloidal particles precipitated as a yellowish or brownish solid. Formaldehyde and acetaldehyde were determined gas by HPLC as dinitrophenylhydrazones. A 5-mL volume of a solution containing 2,4-dinitrophenylhydrazone(400 mg in 100 mL of 2 N HCI) was added to 30 mL of irradiated solution. Cyclohexane, 2 mL, was added after 10 min and the mixture was vigorously shaken for 3 min. A sample of the organic phase was then an(1 1 ) Hart, E. J.; Fischer, Ch.-H.; Henglein, A. Radiat. Phys. Chem., in

press.

(12) Warnatz, J. In Combustion Chemislry; Gardiner, W . C., Ed.; Springer Verlag: Berlin, 1984. (13) Hart, E. J.; Henglein, A. J . Phys. Chem. 1985, 89,4342.

V O ~ . '/o

"

10-6

C,H,

10-~ IC2H21 [MI

10-2

Figure 1. Rate of consumption of acetylene and rates of formation of hydrogen and carbon monoxide as functions of acetylene concentration.

Figure 2. Irradiation of water under mixtures of argon and deuterated acetylene. Yield ratios H2/HD and D,/HD as functions of CzD2concentration.

alyzed by HPLC (Waters R P 18 Cartridge with radial compression, 2 mL/min, 80% methanol-20% water). Formic acid and acetic acid were determined with an ion chromatograph.

Results The effect of the C2H2concentration on the consumption of acetylene and the formation of hydrogen and carbon monoxide are shown in Figure 1. The lower abscissa scale gives the concentration of acetylene in the aqueous solution before irradiation and the upper scale shows the volume percentage of C2H2in the argon-acetylene gas above the liquid. As mentioned above, the yield vs C2H2concentration curve has a maximum, the peak lying M or 5 ~ 0 1 % .The curves for H2 and CO at [C2H2] = 2 X also pass through a maximum (at 6 X lo4 M), which, however, does not coincide with that of C2H2consumption. Also note that almost no C O is formed at the maximum of the C2H2 consumption. Further, more H2 is formed than C2H2is consumed M. It has to be rememat C2H2concentrations below 2 X bered at this point that acetylene is not the only compound that is sonolyzed in the argon bubbles as water vapor is also present. The decomposition of water vapor in argon bubbles leads to Hz, free hydrogen and oxygen atoms H202,and a small amount of 02, and hydroxyl radicals being the intermediates.I3J4 Experiments with deuterated acetylene, C2D2,were also performed in which the D2 and H D yields were determined. The D2 yield also went through a maximum, the position of which is at a much higher M) than that of H2. Very little acetylene concentration (4 X D2 appeared at acetylene concentrations where the yield of H 2 has its maximum, all these observations indicating that different mechanisms of hydrogen formation exist. In Figure 2, the yield ratios D2/HD and H2/HD are plotted as functions of C2D2 concentration. The opposing course of these curves also indicates that at about 1 X M C2D2there is a change in the mechanism of hydrogen formation, Le., in the relative contributions of hydrogen from water and acetylene. Figure 3 shows how the concentrations of H2and C O depend on the irradiation time. As can also be seen, very small amounts of carbon dioxide are also formed. The figure also shows the (14) Makino, K.; Mossoba,

1369.

M. M.; Riesz, P. J . Phys. Chem. 1983,87,

286

The Journal of Physical Chemistry, Vol. 94, No. I , 1990

Hart et ai.

2000

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-

$ 1000 V

0

20

10

30"

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Figure 3. Concentration of various products as function of sonication time. The figure also shows the consumption of acetylene (or the concentration of remaining acetylene) and the scattering-absorban= of the irradiated solution. Initial acetylene concentration in the solution: 1.6 x 10-3 M. 150

0.01 0.1

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Figure 5. Initial rate'of formation of minor products of sonolysis as function of acetylene concentration. 1.0

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Figure 4. Concentration of minor products of sonolysis as function of M. irradiation time. Initial acetylene concentration: 1.6 X decrease in CzH2 concentration as well as the concentration of remaining C2H2. The initial concentration of C2H2in solution M, the total concentration (adding the amount of is 1.6 X C2H2in the gas phase) being 2.6 X M. For sonication periods exceeding about 8 min, over 90% of the acetylene is consumed. The solutions were turbid after sonication which indicates the formation of soot (organic compounds of rather high molecular weight). Figure 3 also shows how the amount of soot depends on irradiation time. The scattering absorbance is plotted as a function of time. The curve obtained roughly parallels that of C2H2consumption; Le., not much additional soot is formed after 5-10 min, when most of the acetylene has been consumed. The curves for Hz and CO production, however, still increase at longer irradiation times. Under these conditions, one is dealing mainly with the sonolysis of water and the products from acetylene sonolysis. Methane and ethylene are also produced in the sonolysis of acetylene. Figure 4 shows how their concentrations vary with irradiation time. While the curve for CH4 shows a behavior similar to that of C2H2consumption in Figure 3 the curve for ethylene reaches a maximum at IO min and then rapidly decreases. C2H4 obviously is a product that itself can readily be sonolyzed. Other products in Figure 4 are COz, acetaldehyde, formaldehyde, and acetic and formic acids. The concentrations of ethylene and acetaldehyde decrease at longer times, while those of formaldehyde and formic acid continue to increase. Gases formed at lower yields are ethane, propene, propyne, allene, and butadiene. Figure 5 shows their yields together with those of methane and ethylene as functions of the CzH2concentration in a double logarithmic plot. These gases show maximum M; they are formed with yields yields again at about 4 X approximately 1/ 10th those of methane and ethylene. The rates given in Figure 5 are initial rates determined in experiments where the irradiation time was no longer than 3 min. In all cases, for sufficiently short irradiation times, the amount of product formed was proportional to the time. Trace concentrations of propane, butene, butyne, and the butanes were also observed. Products having a larger number of C atoms are discussed next. The volatile products were removed continuously as mentioned

A Inml Figure 6. Ultraviolet absorption spectrum of purgeable ,mpounds from a 1.6 X M C2H, solution. Irradiation time: 2 min. The acetylene concentration was kept constant during irradiation by flowing an ArC2H2mixture through the solution.

I

0.5

200

250

200 A Inml

300

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300

Figure 7. (a) Absorption spectrum of an irradiated 1.6 X M CzH2 solution at different times of irradiation. (b) Spectrum of the solutions in part a after purging with argon. in the Experimental Section (procedure 3), i.e., by flowing an acetylene-argon mixture through the sonicated solution and freezing out the products at -80 OC. Figure 6 shows the absorption spectrum of these products. Several bands are seen in the UV region which are probably due to the presence of conjugated dienes, conjugated -ines as well as -enines. Among these compounds, diacetylene and vinylacetylene were identified by mass spectrometry. Similar spectra were observed when the solution, which had been irradiated in the closed vessel, was investigated spectrophotometrically. Figure 7a shows the UV absorption spectrum at different times of irradiation. Note that the intensity of the bands is highest for the shortest irradiation, and progressively lower the longer the time of irradiation. This shows that the compounds that produce the sharp bands are consumed at longer irradiation times when most of the acetylene has been converted. Figure 7b

Pyrolysis of Acetylene

The Journal of Physical Chemistry, Vol. 94, No. I , 1990 281

7

~

9

1

No. of C - Atoms

m m b

b

; Q)

0

Z C

0 %

El5

Figure 9. (Left) Main products (mass numbers) in the irradiation of C2H, solution of various concentrations. Products separated by extraction with ether and analyzed by combined gas chromatography-mass spectrometry. (Right) Relative abundancies of odd and even C number

products.

m

Figure 8. Relative abundances of compounds with mass numbers in the range from 64 to 104 for various acetylene concentrations.

shows the absorption spectra of the solutions of Figure 7a after purging with a stream of argon for 10 min. It can be seen that the volatile compounds that caused the sharp absorption bands were removed, the remaining absorption spectra being structureless and having increased intensity at longer irradiation times. The conclusion is drawn that the nonvolatile compounds in Figure 7b were formed by polymerization of the unsaturated compounds present in Figures 6 and 7a. Figure 8 shows the relative intensities in the gas chromatographic/mass spectrometric investigation of the products that were removed by the flowing acetylene-argon stream. The three diagrams were determined for various steady-state acetylene concentrations. At the lower concentrations (0.46 and 0.94 mM) which lie on the left side of the maximum for acetylene consumption in Figure 1 a rather broad and uniform mass distribution is observed. At the higher acetylene concentration (3.72 mM), which is on the right side of the C2Hzmaximum in Figure 1, the mass 78 peak of benzene is dominant, It should also be mentioned that the chromatogram contained various isomers of benzene at lower concentrations. A chromatogram was taken from the ether extract of an 1.6 X M C2Hzsolution irradiated for 2 min in the closed vessel (experimental procedure 4, see above). It contained a very great number of products in the range of mass numbers up to 160. It was not attempted to identify all products. Only the most abundant ones, including phenylacetylene, styrene, indene, and naphthalene, were identified. The left part of Figure 9 shows that the most uniform distribution of products occurs at an acetylene concentration of 2.42 mM, Le., close to the maximum for C2H2 conversion in Figure 1. At the higher acetylene concentration of 5.1 1 mM, the naphthalene peak is most pronounced. In the diagrams of the right side of Figure 9 the sums of all odd and even C number products in the C7-CIo range are shown. It can be seen that the intensity alternates, the even C numbered products being more abundant than the adjacent odd numbered ones. It is important to note that all the products are formed at constant rate from the very beginning of sonication. Figure 10

6

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100

200

300

[SI Figure 10. Concentration of phenylacetylene (0)and styrene ( 0 )as functions of sonication time for a 2.96 X M C2H2solution. time

shows an example for a 2.96 mM C2Hz solution. The concentrations of phenylacetylene and styrene are plotted here as functions of irradiation time. In both cases the concentration of products is proportional to the irradiation time. Figures 11-13 describe typical experiments on the soot which has already been mentioned in the discussion of Figure 3. Light scattering was found in all sonicated solutions even at the lowest CzHz concentrations applied and after sonication times shorter than 1 min. Superimposed on the light scattering-absorption, which begins beyond 600 nm, is the UV absorption of the unsaturated compounds (Figures 6 , 7 , and 13). In the experiments of Figure 11, rather long irradiation times were used, at which times the unsaturated compounds were already converted into higher polymeric materials. The curves give the scattering-absorbance spectrum immediately after irradiation and after filtration of the irradiated solution through a 4 X IO4 cm pore filter. The scattering after filtration was smaller as the largest soot particles had been removed. Note that the fraction of removed particles increased with increasing irradiation time. It should also be remembered that the acetylene in the closed vessel was consumed after a few minutes (Figure 3). These findings show that the soot particles became larger with time. In the experiments in which an acetylene-argon stream flowed through the solution, large amounts of soot were obtained. At longer sonication times the soot is no longer present as a colloid but as a brownish precipitate. In the experiments of Figures 12 and 13 very short sonication times were applied to find out whether soot formation parallels that of the lower molecular weight products, Le., does not have

0

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Hart et al.

The Journal of Physical Chemistry, Vol. 94, No. I , 1990

compounds only. The scattering-absorption spectrum was obtained as the difference between the spectra before and after filtration. Experiments of this type were also made with longer irradiation times, i.e., 20 and 30 s. The scattering-absorbance at 300 and 400 nm is plotted in Figure 13 as function of irradiation time. The straight lines obtained indicate that soot is formed already in the very beginning of irradiation and its amount is proportional to the irradiation time. The figure also contains the absorbance of the sharp band at 190 nm after filtration which is typical for benzene. Its intensity also is proportional to the time. The elementary composition of soot, produced in 3.4 X and 5.9 X M C2H2solutions, was C 4 8 H 4 2 0which , shows that the decomposition of water contributed to soot formation. At very low C2H2concentrations and short irradiation times the soot absorbed light instead of scattering it. The absorption spectrum extended rather uniformly over the whole UV/vis range.

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400

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A lnml Figure 12. (Dashed line) Absorption spectra of an irradiated 3 X M C2H2solution before and after filtration. (Full line) Difference spectrum due to scattering. Irradiation time: 10 s.

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Figure 13. Scattering-absorbance at 300 and 400 nm and 190-nm absorbance of benzene as functions of sonication time. C2H2:3 X lo-' M. The scattering-absorbance was obtained as the difference of the spectra before and after filtration. The 190-nm absorbance was measured in the filtered solution.

an induction period. As can be seen from Figure 12, the absorption spectrum after sonication contained the sharp bands of unsaturated compounds on the scattering background. After filtration through a 2 X 10" cm pore filter which removed all larger particles the absorption spectrum was due to the lower molecular weight

Discussion Combustion Character ofCzH2Sonolysis. The chemical effects of ultrasound are explained by the hot-spot theories of Noltingk and Neppiras,ls Griffing and co-workers,I6 and more elaborate t h e ~ r i e s . ~According ~ ~ ~ ~ ' ~to the Noltingk-Neppiras concept, a gas nucleus in the liquid grows slowly and isothermally in the ultrasonic field. The mechanism of growth is rectified diffusion17 as the bubble oscillates. The bubble's interior and the surrounding liquid are regions that undergo changes during bubble growth. Molecules diffuse into and out of the bubble, the concentration of gas molecules in the surrounding liquid varies, and hydrophobic molecules in the solution may be accumulated at the interface.2b.3 When a certain bubble size is reached, which is about 5 X cm at a frequency of 1 MHz, it undergoes a rapid adiabatic compression or collapse. Temperatures of several thousand kelvin and pressures of up to 100 bar may be built up during this compression phase. As mentioned in the Introduction, the temperature will be lower with increasing C2H2content of the bubble because of the greater heat capacity of this gas. These conditions are even more drastic than in the combustion and pyrolysis studies on C2Hz that have often been reported.18 It is therefore not surprising that similar products are found in sonolysis and combustion. In our discussion, we will make use of the mechanisms developed in combustion chemistry. However, one should be aware that the sonolytic conditions are unique from various points of view. Firstly, the presence of oxygen is not necessary to initiate the reaction. Secondly, water vapor is present in the bot bubbles which can deliver 0 atoms to build up products containing oxygen. In the third place, the combustion in a cavitation event occurs in less than a microsecond and the products formed are immediately stabilized and cooled by the surrounding aqueous solvent. The number of products from CzHzsonolysis is large. Besides small gas molecules, such as C O and CH4, various hydrocarbons with intermediate C atom numbers, such as benzene and various C&6 isomers, high c number products, such as naphthalene, are formed. All these products have a common property when they are formed: Their concentration is proportional to the irradiation time, even at times as short as 10 s. An important conclusion can be drawn: All these products form in single cavitation events. If a product of higher C number was formed via accumulation of products of intermediate C numbers in the solution and subsequent pyrolysis in other cavitation events, the concentration would have increased in an S-shape manner. ( 1 5 ) Noltingk, B. E.; Neppiras, E. A. Proc. Phys. SOC.1950,863,674. (16) Fitzgerald, M. E.; Griffing, V.; Sullivan, J. J . Chem. Phys. 1956, 25, 926. (17) Atchley, A . A,; Crum, L. A. In Ultrasound, Ifs Chemical, Physical, and Biological Effects; Suslick, K. S., Ed.; VCH Publishers: New York, 1988; P 1.

(18) (a) Miller, J. A.; Mitchell, R. E.; Smooke, M. D.; Kee, R. J. Symp. 1982, 181. (b) Warnatz, J.; Bockhorn, H.; Moser, A.; Wenz, H. W. Symp. (In?.)Combusf.,[Proc.],19 1982, 197. (c) Calcote, H. F. Nato Conf. Ser. 1983.6,197. (d) Westbrook, C. K.; Dryer, F. L. Prog. Energy Combust. Sci. 1984, IO. (e) Wu, C. H.; Singh, H . J.; Kern, R . D. In?. J . Chem. Kinet. 1987, 19, 975. (In?.) Combust., [Proc.],19

The Journal of Physical Chemistry, Vol. 94, No. 1, 1990 289

Pyrolysis of Acetylene As already mentioned above, the temperature reached in a compressed argon bubble depends on its content of acetylene. At low acetylene concentration one expects a high temperature and the sonolysis of water vapor should play an important role. At high acetylene concentration, the temperature will be lower and mainly decomposition of acetylene take place. The First Stages of Water and Acetylene Decomposition. Water is known to dissociate in cavitation bubbles to yield hydrogen atoms and hydroxyl radicals: H2O M H OH M (1)

+

+

+

+

It has previously been shown that oxygen atoms are also generated and that 0 atoms and OH radicals are interconvertible at the high temperatures existing in argon bubble^:^,'^ 20H 0 H2O (2)

-

+

0 + H2O

20H (3) In the pyrolysis of acetylene, the following processes play an important roIe:I8 C2H2 + M C2H + H + M (4) 2C2H2

-

CIH,

+H

(5)

The specific rates of these reactions are known as functions of temperature.'* The temperature in argon cavitation bubbles is 3000 K or higher." In this temperature range the specific rate of water decomposition is higher than that of acetylene. At low acetylene concentrations, where one is dealing with high temperatures, the mechanism should consist mainly of an attack of acetylene by the free radicals and atoms from water. The following reactions are known from combustion studies:18asb C2H2 0 -+ CO + CHI (6)

+

-

+ H + M C2H3 + M C2H + OH CH2 + CO C2H2 + OH CH2CO + H

C2H2

-

+

(7)

(8) (9)

The CHI species formed in reactions 6 and 8 may undergo reactions with radicals leading to CH:IEa CH2 + O H -+ CH H20 (10) CH2 0 + C H OH (11)

+

CH2

+ H -CH

+ + + H2

(12)

The formation of CO via reaction 6 explains why the yield vs C2H2 concentration curve passes through a maximum at relatively low C2H2concentration (Figure 1). At higher concentrations one moves into a range of lower temperatures where reaction 5 is the dominating primary decomposition process, the dissociation of water and acetylene becoming less important. Reaction 5 has the lowest activation energy among all the primary pyrolysis processes. For this reason and also for the bimolecular nature of this reaction, it should become faster than reaction 4 at higher acetylene concentrations and become the most important primary decomposition reaction. The reaction of OH with C2H2according to eq 9 leads to ketene. However, the formation of CO has also been postulatedI9 via the reaction OH + C2H2 CH3 CO (13)

-

+

a methyl radical being formed, too. This reaction explains why methane is such an important product (Figure 4), as the CH, radical may pick up a hydrogen atom. C2H4 may be formed in the reaction of methyl radicals: 2CH3 C2H4 H2 (14)

-

+

At low acetylene concentrations, the H2 yield is greater by a factor of about 2 than the yield of C2H2consumption (Figure 1). (19) Gehring, M.; Hoyermann, K.; Wagner, H. Gg.; Wolfrum, J. Z.Naturforsch. 1970, 25a. 675.

H2 can be formed in dilute solutions by the combination of H atoms from the decomposition of water or via the reaction H H2O H2 OH (15)

-

+

+

In the presence of rather little acetylene, the H2 yield is increased substantially (Figure 1). This is not due to hydrogen coming from acetylene molecules as the experiments with C2D2showed that almost no D2 was formed at these low concentrations. Small amounts of hydrogen peroxide could still be detected at low acetylene concentrations, which indicates that oxidizing species, such as OH radicals and oxygen atoms, were not completely scavenged by C2H2. The increase in H2 yield is attributed to the scavenging of 0 and OH which in the absence of C2H2decrease the hydrogen yield by reactions with H or H2. Isotopic studies with C2D2 have revealed the concentration ranges where the water-initiated reactions play a role, and where the bimolecular pyrolysis reaction 5 begins (Figure 2). D2 is the dominant product at acetylene concentrations above 2 X lo-, M, where the yield of H2 drops to zero. The D2 formation is attributed to direct pyrolysis of C2D2. Formaldehyde and acetaldehyde may be formed from CH3 and C2H5radicals: CH, + 0 CH2O H (16) C2H5 0 -+ CH2O + H (17)

-

+

+

Formaldehyde may also be formed by insertion of CH radicals into water molecules:20 CH H2O CH2OH ---* HCHO H (18) Ketene from reaction 9 may be hydrolyzed to acetic acid CHjCOOH (19) CH,=C=O + H20

-

+

+

+

-

and HCHO oxidized to formic acid: HCOOH HCHO 0

+

(20)

C, and C4 Hydrocarbons. Propyne and allene form in yields about a factor of 10 less than methane and ethylene, whereas propene and propane form in yields lower still (Figure 5). Propyne and allene are probably in equilibrium and formed by the reactiorw2' CH2 + C2H2 C3H3 H (21) C3Hj

+ RH

-

+

+ C3H4 + R

(22)

CH,-CECH CH2=C=CH2 (23) Butadiene, diacetylene, and vinylacetylene have been identified. There exists a group of intensely absorbing compounds that have absorption bands at 200, 214, 224, 245, 260, 273, and 295 nm (Figure 6 and 7). These volatile compounds, when left in the solution, react to form nonpurgeable derivatives that absorb the scatter light (Figures 7b and 13). These compounds have not been identified, but their banded structures suggest mixed polyenesynes. For example, the 245-nm band of Figure 6 is the same as the 244-nm band of R-(CH=CH)-(C=L),-(CH=CH)-R with t = 23000 M-l cm-I. The 295-nm band is close to the with t = 31 000 294-nm band of R-(CH=CH),-(C=C),-R M-l cm-I 22 Products of Greater C Atom Number. The similarity of the products with those reported in combustion studies provides excellent evidence that the sonolysis of acetylene generates compounds that are similar if not identical with those found in flames and shock tubes.23 -+

(20) Zabarnick, S.; Fleming, J. W.; Lin, M. C. Symp. (Int.) Combust., [Proc.],21 1988, 713. (21) Vinckier, C.; Schaekers, M.; Peeters, J. J . Phys. Chem. 1985,89,508. (22) Bohlmann, F.; Burkhardt, T.; Zdero, C. Naturally Occurring Acetylenes; Academic Press: London, 1973. (23) (a) Frenklach, M.; Clary, D. W.; Gardiner, W. C.; Stein, S. E. Symp. (Int.) Combust., [Proc.],21 1988, 1067. (b) Bittner, J. D.; Palmer, H. B. In Soot Formation in Combustion Systems and Its Toxic Properties; Plenum Press: New York, 1983. (c) Frenklach, M.; Clary, D. W.; Gardiner, W.C.; Stein, S. E. Symp. (Inr.) Combust., [Proc.], 20 1985, 887. (d) Harris, S. J.; Weiner, A. M.; Blint, R. J.; Goldsmith, J. E. M. Symp. (Int.) Combust., [Proc.],21 1988, 1033.

290

The Journal of Physical Chemistry, Vol. 94, No. 1, 1990

The main precursor of the products that contain a greater number of C atoms is possibly C4H3formed in reaction 5. It can react according to C4H3

+M

+

C4H2 + H

+M

(24)

the activation energy being 59.7 kcal/mol.'sa Diacetylene, C4H2, is formed in this reaction. It is a very reactive species through which many higher hydrocarbon products including soot are possibly produced. C4Hz is also formed in a reaction of C2H (see eq 4):Isd C2H2

+ CZH

4

C4H2

+H

(25)

Diacetylene can also react with the O H radical:Isd C4H2

+ OH

-+

C3H2

+ HCO

(26)

The sequence of reactions 25 and 26 plays an important role in C2H2combustion. H C O may be a precursor of formaldehyde. C3H2 is an unsaturated carbene which could also be the precursor of many products of higher C atom number. The relative proportion of products in the C5-C7 range is strongly dependent on the C2H2concentration. In the 0.46 mM solution of Figure 8 the nonaromatic Cs and c6 hydrocarbons form a greater portion relative to the aromatic compounds than in the 0.94 and 3.72 mM CzH2solutions. These nonaromatic compounds have the compositions CsH4, C&, C6H2, C6H4, C6H.5, and C7Hs and consist of di- and triacetylenes as well as mixed olefin-acetylenes. These compounds may be identical with those responsible for the absorption bands in Figures 6 and 7, extending from 200 to 300 nm. Compounds of higher mass have been obtained from ether extracts of the irradiated solutions. Only the most abundant ones have been positively identified. Again the relative proportion of these products is a function of C2H2concentration (Figure 9). The fact that higher products with an even C atom number are found more frequently than those with an odd C atom number (Figure 11) indicates that polymerization and condensation reactions of an even number precursor, such as diacetylene, play a dominant role. The formation of diacetylene as the first intermediate to form solid carbon and hydrogen has already been discussed in the early shock tube work on soot formation.24 The aromatic compounds benzene, styrene, phenylacetylene, indene, and naphthalene are prominent products of C2H2sonolysis, (24) Greene, E. F.; Taylor, R. L.; Patterson, W. L. J . Phys. Chem. 1958, 62, 238.

Hart et al. especially in the concentration range above 1 mM. In the sonolysis of aqueous benzene solutions (unpublished work) C2H2is a very important product, so there is an interconversion of CzH2 and C6H6, just as is reported in c o m b ~ s t i o n . ~ ~ Soot Formation. The absorption spectrum of very small soot particles resembles that of a black substance. It could be the spectrum of graphite particles. One therefore may conclude that the pyrolysis at the highest temperatures, Le., lowest C2H2concentrations, leads partly to complete stripping off of all hydrogen atoms in acetylene. Carbon formation has been attributed to the reaction26 CH H + C H2 (27) The pathways to soot formation have been treated in the combustion l i t e r a t ~ r e . ' ~ ~Polycyclic - ~ ~ ~ ~ ~hydrocarbons ~ are considered to be a major component of soot. And soot is defined as the fraction of carbon accumulated in species larger than ~ o r o n e n e .Although ~~~ the mechanism of acetylene pyrolysis remains unchanged in an oxidative environment, combustion soot is considered primarily to consist of hydrogen and carbon, although oxygen is reported in some soot. The sonolytically produced soot contains about 1 oxygen atom per 5 carbon atoms. Up until now we have mentioned only free-radical reactions to explain the formation of various products. It should, however, be remembered that ion-molecule reactions can occur under comparable conditions, Le., in flames and shock tube experiments.2s Ionic reactions, which often are faster by orders of magnitude than radical reactions, become possible when chemiionization processes occur between radicals and atoms, such as

+

+

+

+

C H 0 CHO+ e(28) the CHO+ ion initiating various reactions with neutral molecules including the polymerization of C2Hz. 4

Acknowledgment. We thank U. Michalczik for excellent assistance in the analytical work. This work was supported by Fonds der Chemischen Industrie and Deutsche Forschungsgemeinschaft. Registry No. C2H2, 74-86-2; H20, 7732-18-5. (25) Baldwin, R. R.; Scott, M.; Walker, R. W .Symp. (Inr.)Combust., [Proc.], 21 1988, 991.

(26) Thorne, L. R.; Branch, M. C.; Chandler, D. W.; Kee, R. J.; Miller, [Proc.], 21 1988, 965. (27) Homann, K. H. Symp. (Int.)Combust., [Proc.], 21 1988, 857. (28) (a) Calcote, H. F.; Olson, D. B.; Keil, D. G. Am. Chem. SOC.,Diu. Fuel Chem. 1987,32,524. (b) Hayhurst, A. N.; Jones, H. R. N. Symp. (Int.) Combust., [Proc.],20 1985, 1121. (c) Keil, D. G.; Gill, R. J.; Olson, D. B.; Calcote, H. F. Symp. (Int.) Combust., [Proc.], 20 1985, 1129.

J. A. Symp. (Int.) Combust.,